Maximum integrator gain of PID on performing position control of DC motor in the presence of Stribeck friction: Kalman conjecture approach

The application of PID to perform position control in the presence of Stribeck friction is believed to provoke the system trapped in limit cycle oscillation. This research aims to investigates the formulation of PID that will stabilize the position control of DC motor in the presence of Stribeck fri...

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Veröffentlicht in:	IOP conference series. Materials Science and Engineering 2019-10, Vol.645 (1), p.12012
Hauptverfasser:	Tumbuan, T P, Nurprasetio, I P, Indrawanto, Abidin, Z
Format:	Artikel
Sprache:	eng
Schlagworte:	D C motors Electric motors Friction Limit cycle oscillations Proportional integral derivative Stability analysis
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description	The application of PID to perform position control in the presence of Stribeck friction is believed to provoke the system trapped in limit cycle oscillation. This research aims to investigates the formulation of PID that will stabilize the position control of DC motor in the presence of Stribeck friction. In order to diminish the limit cycle oscillation, the PID gain is set to meet global asymptotic stability in Lyapunov sense as Kalman conjecture is fully applied. The analysis shows that the stability of the system depends on the friction properties near Stribeck velocity. Furthermore, the proposed PID formulation is found to be easy to be applied as the maximum integrator gain applied to the system is directly proportional to the given proportional gain.
doi_str_mv	10.1088/1757-899X/645/1/012012
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subjects	D C motors Electric motors Friction Limit cycle oscillations Proportional integral derivative Stability analysis
title	Maximum integrator gain of PID on performing position control of DC motor in the presence of Stribeck friction: Kalman conjecture approach
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